细胞色素P450与除草剂代谢

细胞色素P450是广泛存在于生物中的一类具有混合功能的血红素氧化酶。P450对除草剂代谢的机制及反应类型是多样的,与除草剂代谢相关的P450基因的植物转基因研究得到了具有不同除草剂抗性的转基因植物。文章就这方面的研究进展作介绍。     

植物谷氨酰胺合成酶研究进展及其应用前景

氮素是制约作物产量的主要营养元素之一,谷氨酰胺合成酶(Glutamine synthase,GS;EC 6.3.1.2)是氮素代谢途径中的关键酶。目前,拟南芥、水稻、小麦和玉米等植物中的GS成员均已被分离鉴定。研究表明,超表达GS能够提高植物对氮素的利用效率,从而在植株的生长发育特别是产量形成过程中发挥重要作用,但是其功能在不同植物上并不完全一致,可能与GS基因受到转录和翻译后等水平的调控有关。以下综述了植物GS基因分类、QTL定位、对氮素代谢响应、组织表达特异性、生物学功能及其分子调控机制等方面的研究进展,并展望了植物GS基因的应用前景,以期为利用GS基因来提高植物氮素利用效率提供具有参考价值的信息。     

一种新型几丁质酶基因LcChi2在转基因水稻中的功能分析

LcChi2是从羊草中克隆获得的一种新型几丁质酶基因,生物信息学分析表明该基因表达一个Ⅱ类几丁质酶,属于19家族。在双子叶模式植物烟草中过表达该基因表现为抗真菌病害的生物学功能提高,然而在单子叶植物中是否具有抗病功能至今未知。以吉林省主栽水稻品种吉粳88为供试材料,构建了含LcChi2基因和除草剂筛选标记Bar基因的双价植物表达载体,利用农杆菌介导的遗传转化方法成功获得LcChi2和Bar基因过表达的转基因水稻。T_1代转基因水稻的PCR、RT-PCR和几丁质酶活性检测结果表明LcChi2基因已成功整合到水稻基因组中,并且表达产物表现出较高的外源几丁质酶活性;稻瘟病活体接种实验结果证明该基因显著提高了水稻的抗病性;抗除草剂鉴定结果表明获得的转基因水稻新材料同时具有除草剂抗性。研究结果证明LcChi2基因可有效提高单子叶植物的抗病性,该基因在利用现代生物技术开展抗病作物遗传改良方面具有重要的应用价值。     

植物丝氨酸羧肽酶及其类蛋白的研究进展

丝氨酸羧肽酶（serine carboxypeptidases,SCP）是一类属于α/β水解酶家族的蛋白酶,在植物生长发育过程中参与多肽和蛋白质的加工、修饰与降解等多个重要环节,并且在许多生化途径包括次生代谢产物的生物合成、催化酰基转移、除草剂共轭和种子萌发相关蛋白质降解中起重要作用。介绍和评述了植物丝氨酸羧肽酶及其类蛋白的种类、特点、功能及其基因的表达调控,并对植物丝氨酸羧肽酶及其类蛋白的研究方向和应用提出了展望。     

6b基因:植物肿瘤形成的重要影响因子

近年来,来自农杆菌的致瘤基因在植物中的功能和作用机理研究越来越得到重视。6b基因是植物肿瘤形成的重要影响因子,它位于T-DNA片段上,属于rolB基因家族。在植物体内,6b基因能影响激素水平、糖的含量和其他次生代谢产物的积累,以及改变与其相关基因的表达水平等,但其具体作用机制还有待深入研究。文章对6b基因的生物功能、分子结构、活性部位、作用模式等方面的重要研究进行了综述,为这类功能基因的进一步研究及应用提供了理论依据。     

植物非共生血红蛋白的研究进展

植物非共生血红蛋白（nsHb）基因在植物界广泛存在。许多生物和非生物胁迫可以诱导nsHb的表达。nsHb在植物的生长发育和逆境胁迫中具有重要功能,其作用机制与NO的代谢密切相关。文章综述了非共生血红蛋白的表达特性、生物学功能及其作用机制等方面的研究进展。     

植物的血红蛋白

近几年来,植物血红蛋白的研究进展十分迅速,豆科植物中与共生固氮无关的血红蛋白基因和包括禾本科植物在内的许多非豆科植物血红蛋白基因的发现使人们对植物血红蛋白有了新的认识,进而把植物血红蛋白分为共生血红蛋白和非共生血红蛋白两种类型。对这两种血红蛋白的性质、功能、基因结构及表达等方面的研究不仅对共生固氮中植物与微生物的相互关系和固氮工程研究;而且对植物细胞的呼吸代谢和耐涝机理等研究有重要价值。     

对氨基苯甲酸酯同系物形成细胞色素P450代谢中间体络合物的定…

细胞色素Ｐ４５０（Ｐ４５０,Ｅｃ,１．１４．１４．１）是一种十分重要的催化氧化反应的酶,本文测定了１２个对氨基苯甲酸酯用系物与Ｐ４５０相互作用而形成Ｐ４５０代谢中间体络合物的活性,用半经验分子轨道法ＭＮＤＯ－ＰＭ３计算得到了这些同系物的分子轨道指数,并用逐步多元回归分析法导出了活性与分子轨道指数及正辛醇／水分配系数的对数值之间的定量结构与活性关系。结果表明,对苯氨基苯甲酸脂同系物形成Ｐ４５０代谢中     

人工合成的植物化猪α乳清蛋白基因在转基因拟兰芥的表达

将一个398bp的植物化的猪α乳清蛋白基因(Lactalbumin,LA)编码区克隆到带有花椰菜花叶病毒的35S启动子的质粒中。对它们进行PCR检测和序列分析,证实这些阳性克隆是实验预期的重组质粒。随即将35S启动子-α-乳清蛋白基因-终止子这一表达单元克隆到双元载体pCG-CB中,用该重组质粒双元载体pCG-CB-Lact转化农杆菌V3101后,以农杆菌法进行拟兰芥植物转化,用除草剂Finale对转化植物进行抗除草剂基因筛选,得到一些抗除草剂的转化植株。对这些抗除草剂植株进行猪α乳清蛋白基因PCR分析,成功筛选到带有猪α乳清蛋白基因并且可以在后代稳定遗传的转基因植物。Western blot蛋白质表达分析,表明猪α乳清蛋白在拟兰芥中成功表达,并且猪仅乳清蛋白被正确加工成天然蛋白。     

高等植物赤霉素2-氧化酶基因的克隆、表达及其调控

赤霉素(GA)是一类重要的植物激素,对高等植物整个生命周期的生长发育起关键作用。调控赤霉素生物合成和代谢途径中的关键酶基因的表达可以控制植物体内赤霉素的含量。GA2-氧化酶是调节赤霉素合成和代谢的关键酶之一,使活性GA失活。本文主要对GA2-氧化酶基因的克隆、表达调控及其在植物基因工程中的应用等方面进行综述,为通过基因工程技术调控植物体内活性赤霉素的含量从而得到改良品种提供思路。     

Plant Cytochrome P450 Monooxygenases

Plant systems utilize a diverse array of cytochrome P450 monooxygenases (P450s) in their biosynthetic and detoxification pathways. The classic forms of these enzymes are heme-dependent mixed function oxidases that utilize NADPH or NADH and molecular oxygen to produce functionalized organic products. The nonclassical forms are monooxygenases that either do not utilize flavoproteins for dioxygen activation or fail to incorporate molecular oxygen into their final product. Biosynthetic P450s play paramount roles in the synthesis of lignin intermediates, sterols, terpenes, flavonoids, isoflavonoids, furanocoumarins, and a variety of other secondary plant products. Other catabolic P450s metabolize toxic herbicides and insecticides into nontoxic products or, conversely, activate nontoxic substances into toxic products. Biochemical and molecular characterizations on a number of plant P450s have indicated that the relationships between these heme proteins and their substrates are at least as complex as those that exist in mammalian systems. Examples now exist of plant P450s that metabolize: a narrow range of substrates to yield different products, a single substrate to yield different products, multiple substrates to yield the same product, or a single substrate sequentially to yield discrete intermediates in the biosynthesis of a single product. Extensive divergence of catalytic site as well as noncatalytic site residues accounts for the high degree of primary structure variation in the P450 gene superfamily and the diverse array of substrates synthesized and/or detoxified by these proteins. Classic P450s still retain a highly conserved F-G-R-C-G motif in their catalytic site and conserved amino acids in their oxygen binding pocket; nonclassical P450s diverge at several of these positions. A broad range of cloning and transient expression strategies are suitable for plant P450 studies and these have allowed for the isolation and characterization of a number of P450 cDNAs and genes. Because many of these sequences have been cloned only recently, much remains to be learned about the substrate specificities of P450 reactions in plants and the mechanisms by which their genes are regulated.     

Homology modeling of plant cytochrome P450s

Plant P450 monooxygenases represent the largest family of plant proteins and the largest collection of P450s available for comparative studies and biotechnological applications. They have been shown to catalyze a diverse array of difficult chemical reactions and have demonstrated potential to be used in pharmacological, agronomic and phytoremediative applications. Central to our use of these catalytically competent enzymes is the need to understand their interactions with substrates. Because most characterized plant P450s are membrane-bound proteins that are resistant to standard X-ray and NMR structure determinations, homology modeling represents a reliable and relatively rapid alternative method for analyzing structure-function relationships and predicting substrates for many P450s that are only now being characterized. These methods, which are being widely used in mammalian P450 structure-function studies, can allow plant biologists to define critical residues interacting with substrates and, in a directed fashion, alter the reactivities of individual monooxygenases. The homology modelings that have been done on a limited number of plant P450s and the site-directed mutations that validate them indicate that current modeling and substrate docking procedures are capable of providing structural explanations for sequence variants as well as for predicting functional characteristics of undefined P450s.     

Intron-exon organization and phylogeny in a large superfamily, the paralogous cytochrome P450 genes of Arabidopsis thaliana

The cytochrome P450 gene superfamily is represented by 80 genes in animal genomes and perhaps more than 300 genes in plant genomes. We analyzed about half of all Arabidopsis P450 genes, a very large dataset of truly paralogous genes. Sequence alignments were used to draw phylogenetic trees, and this information was compared with the intron-exon organization of each P450 gene. We found 60 unique intron positions, of which 37 were phase 0 introns. Our results confirm the polyphyletic origin of plant P450 genes. One group of these genes, the A-type P450s, are plant specific and characterized by a simple organization, with one highly conserved intron. Closely related A-type P450 genes are often clustered in the genome with as many as a dozen genes (e.g., of the CYP71 subfamily) on a short stretch of chromosome. The other P450 genes (non-A-type) form several distinct clades and are characterized by numerous introns. One such clade contains the two CYP51 genes, which are thought to encode obtusifoliol 14a demethylase. The two CYP51 genes have a single intron that is not shared with CYP51 genes from vertebrates or fungi, or with any other Arabidopsis P450 gene. Only a few of the Arabidopsis P450 genes are intronless (e.g., the CYP710A and CYP96A subfamilies). There was a relatively good correlation between intron conservation and phylogenetic relationships between members of the P450 subfamilies. Gene organization appears to be a useful tool in establishing the evolutionary relatedness of P450 genes, which may help in predictions of P450 function.     

植物细胞色素P450基因的异源表达系统研究进展

细胞色素P450氧化酶是一类具有多种催化功能含血红素的氧化酶系。由于参与多种类型的氧化反应,在植物生命活动中有重要功能,其研究一直受到重视。自1990年第一个植物P450基因成功克隆以来,到2002年年底,已有600多个P450基因被克隆,有100多个基因在细菌、酵母、杆状病毒昆虫细胞等异源表达系统中成功表达并鉴定了功能。拟对植物P450的大肠杆菌、酵母、杆状病毒昆虫细胞表达系统的特点进行比较,对在各表达系统中成功表达并进行了功能鉴定的植物P450进行归纳,并对目前植物P450异源表达的现状和应用进行概述。     

细胞色素P450基因及其在植物改良中的应用

细胞色素P450是一类含血红素的氧化还原酶类,它参与多种生化反应,在防御生物免受病虫害及逆境胁迫等方面具有重要作用。生物基因组序列分析表明,它是一个基因超家族。许多细胞色素P450基因已被鉴定和克隆,并应用于植物遗传改良;在转基因培育多抗性植物、创造植物雄性不育系,提高植物降解化学农药残留等污染物的能力和有效生产具有药用价值的化合物等方面已取得可喜进展,显示出广阔的应用前景。 Abstract:Cytochrome P450s are heme-containing mixed-function oxidases,involving in lots of biochemical reactions.They play an important role in preventing plants from pathogen and insect attacks and environmental stress.Sequence analysis of genomes has revealed that P450 is a gene super-family.Many cytochrome P450s have been characterized and cloned.Some of them have been used in plant genetic improvement.A great progress has been made in using these P450 genes to create the transgenic plants with multiple resistances,male sterility,higher capability to dissolve toxic chemicals and pollutants and effective productivity of high valuable compounds,indicating P450 genes have a broad prospect with great potential application.     

Cytochromes P450 in phenolic metabolism

Three independent cytochrome P450 enzyme families catalyze the three rate-limiting hydroxylation steps in the phenylpropanoid pathway leading to the biosynthesis of lignin and numerous other phenolic compounds in plants. Their characterization at the molecular and enzymatic level has revealed an unexpected complexity of phenolic metabolism as the major route involves shikimate/quinate esters and alcohol/aldehyde intermediates. Engineering expression of CYP73s (encoding cinnamate 4-hydroxylase), CYP98s (encoding 4-coumaroylshikimate 3′-hydroxylase) or CYP84s (encoding coniferaldehyde 5-hydroxylase) leads to modified lignin and seed phenolic composition. In particular CYP73s and CYP98s also play essential roles in plant growth and development, while CYP84 constitutes a check-point for the synthesis of syringyl lignin and sinapate esters. Although recent data shed new light on the main path for lignin synthesis, they also raised new questions. Mutants and engineered plants revealed the existence of (an) alternative pathway(s), which most likely involve(s) different precursors and oxygenases. On the other hand, phylogenetic analysis of plant genomes show the existence of P450 gene duplications in each family, which may have led to the acquisition of novel or additional physiological functions in planta. In addition to the main lignin pathway, P450s contribute to the biosynthesis of many bioactive phenolic derivatives, with potential applications in medicine and plant defense, including lignans, phenylethanoids, benzoic acids, xanthones or quinoid compounds. A very small proportion of these P450s have been characterized so far, and rarely at a molecular level. The possible involvement of P450s in salicylic acid is discussed.     

Cytochromes P450 in gibberellin biosynthesis

The gibberellins (GAs) are an important class of plant growth regulators that are active in many aspects of plant growth and development. GAs are synthesized by a complex pathway involving three enzyme classes spanning different subcellular compartments. One of these enzyme classes is the cytochrome P450s which catalyze a number of oxidation steps in the middle part of the pathway. Mutants in these cytochrome P450-mediated steps in a number of species have been crucial in isolating the genes encoding these enzymes and have also played an important role in understanding GA physiology. GAs are also synthesized by fungi, in a biosynthesis pathway largely catalyzed by cytochrome P450s. The fungal pathway appears to have evolved independently to that of higher plants.

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玉米螟P450基因cDNA的克隆及植物次生物质对其诱导表达

昆虫细胞色素P450是一类在生物代谢中起重要作用的基因家族,承担着许多重要的生 理功能,包括对植物次生物质代谢和杀虫剂解毒等.本研究以玉米螟5龄幼虫中肠的总RNA为 模板,根据不同昆虫P450基因家族保守氨基酸序列,设计并合成简并引物,利用RT-PCR扩 增出了玉米螟细胞色素P450基因cDNA片段,将其克隆到pMD19 T载体进行序列测定.测序获得了编码213个氨基酸残基的641 bp的DNA片段,命名为OfP450(GenBank登录号：EU807990) ;与已公布的棉铃虫、家蚕、欧洲防风草结网毛虫、小菜蛾和黑腹果蝇等的细胞色素P450氨基酸序列进行比较,其一致性分别为55％、50％、49％、44％和31％.将植物次生物质棉酚、丁布添加入人工饲料中,对玉米螟进行了饲喂实验,采用优化半定量RT-PCR,以18S rRNA为内标,RT-PCR检测进食棉酚、丁布植物化合物的玉米螟中肠P450基因的转录. 结果表明,其转录水平能被棉酚、丁布显著诱导. 提示本实验克隆的玉米螟细胞色素P450对植物次生物质的代谢作用与P450表达量呈正相关.该研究为下一步将植物介导的RNA干扰技术应用于害虫生物防治提供坚实的基础.     

P450s in plant-insect interactions

Cytochrome P450 monooxygenases (P450s) are integral in defining the relationships between plants and insects. Secondary metabolites produced in plants for protection against insects and other organisms are synthesized via pathways that include P450s in many different families and subfamilies. Survival of insects in the presence of toxic secondary metabolites depends on their metabolism by more limited groups of P450s. Examples of functionally characterized plant and insect P450s known to be involved in these interactions are discussed in terms of their diversities, reactivities and regulators. These and future examples, which will be uncovered as the fields of plant biology and entomology converge on this interesting area, provide much insight into the array of plant metabolites that are mainline defenses against insects, the range of insect monooxygenases that inactivate these compounds and the evolutionary processes occurring as these organisms wage daily battles with one another. Molecular perspectives on these interactions will provide the scientific community with information critical for genetic manipulation of these organisms aimed at enhancing plant resistance to insects and eliminating insect resistance to natural plant toxins and synthetic insecticides.